Method and system for utilization a fluctuated wind

ABSTRACT

The present method and system provides: conversion of always fluctuating wind into a variable AC electrical power P through wind turbine and electrical generator; consuming its variable AC power with accordance of an equation P−Pc−Pv=0; conversion of the variable AC power is drawing from two phases of an electrical generator into an AC power connected to an electrical grid through an six-pulls diode rectifier, first heat energy exchanger, DC capacitor and DC-AC inverter; conversion a variable AC power drawing from third phase of an electrical generator into heat through switches connected to a neutral line or into a constant voltage DC power through an six-pulls bridge rectifier, second heat energy exchanger and DC capacitor; permanently keeping the rectified variable DC voltage is higher than a DC constant voltage at the buffer capacitor.

United States patent 7,015,595 September 2006 Feddersen, et al. 7,075,189 July 2006 Heronemus, et al. 7,233,079 June 2007 Cooper 7,579,702 September 2009 Park, et al. 7,748,958 July 2010 McVeigh, et al. 7,922,449 April 2011 Scholte-Wassink 8,207,624 June 2012 Gonzales 20030223868 December 2003 Dawson, Mark H., et al. 20080317600 December 2008 Enevoldsen; Peder Bay; et al. 20090047116 February 2009 Barbu; Corneliu; et al.

REFERENCES CITED

-   [1] D. Berry et al., “Parametric study for large wind turbine     blades” -   [2] G. Gail, et al., “Controller design and analysis of a variable     speed wind turbine with doubly-fed induction generator” -   [3] M. Schmidt, “Wind turbine design optimization” -   [4] M. Hansen, “Aerodynamics of wind turbines” -   [5] E. Hau, “Wind turbine fundamentals, technologies, application,     economics” -   [6] J. Manwell, et al., “Wind energy explained theory, design and     application” -   [7] G. Shrestla, et al., “Direct drive wind turbine generator with     magnetic bearing” -   [8] J. Pramod, “Wind energy engineering” -   [9] J. Tangier, “The evolution of rotor and blade design” -   [10] M. Rasila, “Torque and speed control of a pitch regulated wind     turbine” -   [11] G. Jonson, “Wind energy system” -   [12] Z. Chen et al., “Evaluation of various variable speed wind     generator systems” -   [13] R. C. Seidel, et al., “Power train analysis for turbine,     generator” -   [14] Z. Chen, E. Spodner, “Grid power quality with variable speed     wind turbines” -   [15] M. Ragheb, “Wind Power Systems”. Harvesting the Wind -   [16] T. Ackerman, Ed. “Wind Power in Power Systems” -   [17] T. Maritz, “Straight talk about PWM AC drive harmonic problem     and solutions” -   [18] Roger C. Dugan, Mark F. MaGranaghan, H. Wayne Beaty, Electrical     Power Systems Quality. McGraw-Hill Inc. 1996

FIELD OF THE INVENTION

The present invention relates generally to wind turbines operation, and particularly to a method and system for conversion of always fluctuating wind into variable electrical power and fully consuming its variable electrical power.

BACKGROUND OF THE INVENTION

Some of the most important features are the stability of operation of the wind conversion system and the ability its conversion system to feed the connected electrical greed with constant parameters as voltage and frequency. Presently the up-to-date a typical wind conversion system utilizes a constant or variable speed of rotation technology. The basic of its technology is to maintain an average mechanical power on the wind turbine shaft; to average electrical power on the output of the generator; and directly or through electronic converter to connect output of a generator to a grid. Its technology of conversion wind into the average mechanical power presented on the wind turbine shaft is contradicted to naturally blowing the always fluctuating wind. Furthermore, naturally blowing the always fluctuating wind above and below a wind turbine hub is different as a fact of dependency wind speed on roughness classes, wind shear (the different wind kinetic energy contents in the upper and lower levels of rotating blades) and gusts (kinetic energy arises or drops from the fluctuated wind). For reducing instability, oscillating, vibrating and mechanical stresses in the wind conversion system produces by the wind shear and gusts, gravity and pass a tower most wind turbine manufactures prefer to utilize three blade wind turbines and aerodynamically pitch regulation technology. The disadvantage of keeping stability of the current wind conversion system and the ability to feed the connected greed with constant parameters is an additional cost of the wind power plant and limitation to kinetic energy drawn from the always fluctuating wind. Basically the cost of the wind power plant depends on the wind turbine diameter and weight, wherein the blade weight depends on the torque, blades length, surviving wind speed and building blades material. The blade weight influences to the weight, such as rotor, hub, nacelle, drive train, tower, and foundation. The cost of the wind power plant also depends on: utilizing a variable rotor speed generator e.g. doubly fed induction generator (DFIG); complexity of the power electronics, such as AC-DC-AC power converter; utilizing peaks power; utilizing dependable on peaks power higher generator and transmission capacity.

The present invention tries to resolve some restrictions to the systems and apparatuses, which are involved in the process of conversion the always fluctuated wind into the variable electrical power.

SUMMARY OF THE INVENTION

The present invention provides a method for a direct conversion of an always fluctuating wind into a variable mechanical power.

Furthermore, the present invention provides a method for conversion a variable mechanical power into a variable electrical power.

Furthermore, the present invention provides a method for converting a fluctuating wind into a variable mechanical power by at least one blade wind turbine wherein: the variable mechanical power produced by the one blade wind turbine is collected on the carousel and transmitted from the carousel to an electrical generator through the counterweight; the weight of rotational part of the wind turbine keeps on the two bears.

Furthermore, the present invention provides a method for eliminating the average mechanical power presented on the shaft of the wind turbine comprising of eliminating step of utilizing weight of the wind turbine as a fly-will. Wherein, weight of the turbine as the fly-will involves in the process of conversion wind into kinetic energy during rotation a blade above a hub and then conversion its stored kinetic energy into mechanical power on a shaft of the wind turbine during rotation of the blade below the hub. Its stored mechanical kinetic energy needs for compensation losses dependable on wind shear and blade pass a tower and involve in the process of averaging mechanical power on the shaft by a current method of conversion wind into a mechanical power.

Furthermore, the present invention provides a method based on strict limitation to the voltage and frequency of produced electricity connected to the grid and desirable limitation to the voltage and frequency of produced electricity connected to local usages e.g. production of heat, hydrogen and compressed air.

Furthermore, the present invention provides a method for completely consuming the variable electrical power P produced by an electrical generator with accordance of the equation P−Pc−Pv=0 (1). Wherein, the variable electrical power P comprising a constant and variable electrical powers Pc and Pv.

Furthermore, the present invention provides a method for simultaneously drawing electrical power from two phases of a generator for feeding local usages and grid and drawing inconvenience of electrical power from a third phase of a generator for feeding local usages wherein, voltages of the third phase not involved in the process of conversion an AC variable voltage into six-pulls DC variable voltage.

Furthermore, the present invention provides a method for permanently keeping the rectified variable DC voltage which is higher than a DC constant voltage at the capacitor.

Furthermore, the present invention provides a method for conversion of the variable electrical power Pv into heat through a heat energy exchanger.

Furthermore, the present invention provides a method for conversion of the variable electrical power P into a constant electrical power Pc through a six-pulls diode rectifier, heat energy exchanger and DC capacitor.

Furthermore, the present invention provides a wind conversion system based thereon method of extraction a variable electrical power from naturally blowing a fluctuated wind.

Furthermore, the present invention provides a wind conversion system based thereon method of extraction a variable electrical power from naturally blowing a fluctuated wind that is compatible with any wind turbines.

Furthermore, the present invention provides a wind conversion system based thereon method of controlling wind turbines operation by stall, pitch and variable speed techniques.

Furthermore, the present invention provides a wind conversion system by completely consuming the constant and variable electrical powers Pc and Pv by involving in the process of consuming the variable electrical power: the regular electrical generator, six-pulls diode rectifier, six-pulls transistor rectifier, heat energy exchangers; capacitors, DC-AC power inverter and switches. Wherein, the heat energy exchangers utilized the inconvenience for transmission the variable electrical power and in the forms of production of heat, hydrogen and compressed air.

The efficiency of the present wind power turbine is high because it utilizes of all static and dynamic parts of energies content in the wind; wind turbine extracts maximum mechanical power from the wind at the condition of maintaining the optimum tip speed ratio; mechanical power extracted from the wind depends only on the wind variation for a typical site (Weibull Distribution); the limitation to the blade tip speed (noise consideration); the law of extracting power from the wind energy (Betz criterion, Cp=0.593); the limitation of mechanical strength and stiffness of wind turbines, towers, generators and gearboxes; and restriction in absorbing higher wind speed by the blades width (fluctuating wind speed is higher than the optimal for the given blade width, the fluctuating wind will become turbulent and convert from a positive force to a negative force).

The present invention helps to resolve in the future problem associated with fossil fuel. The customers in the U.S. typically consume about 30% of electrical energy, 30% of heat energy and 30% of fuel energy which is spent on transportation e.g. transportation of agriculture production. In the future, most problem of production of electrical energy associates with increasing cost of fossil fuel and the climate changes. The climate changes we see as malting ice (pure water), reducing concentration of salt in the ocean water and increasing water level in the ocean around 3 mm a year. Wherein, the salt water evaporates at 103 C degrees and pure water at 100 C degrees. It means that the reduced concentration of salt in the ocean will evaporate more water at the same amount of sun radiation during a day. Results of increasing the evaporated water that is increased the catastrophic flooding a lot of land, destroying agriculture farm's land is needed for agriculture production e.g. vegetables and fruits.

In the future for compensation of the destroyed agriculture land the agriculture production will be on a way relative to industrial technology, such as vertical construction growing plants, exploitation of greenhouses during a year and built ones closely to customers.

The present wind conversion system includes at least one blade wind turbine. Wherein, the one blade wind turbine transmits torque stored on the carousel to the drive train through the counterweight.

The benefit of using one or two-blade wind turbine compared to three blade wind turbine is a reduction of the wind turbine system cost and weight (blade, gearbox, generator, hub, nacelle, tower, foundation) and higher rotational speed of wind turbines.

In the present wind turbine, the control system permits to extract maximum mechanical power from the naturally blowing wind: by instantly utilizing static and dynamic components of wind energies and keeping the rotor aerodynamic efficiency in light winds high; producing and consuming the variable electrical power with accordance of the equation (1); increasing the operating time by collecting and storing the hydrogen and/or compressed air; returning back it's stored the hydrogen and/or compressed air to the wind conversion system during peak hours or directly to customers.

The present method of production and consuming the variable electrical power with accordance of the equation (1) satisfies: the requirement of completely consuming the mechanical power produced by the wind turbine (in other words, any change of wind kinetic energy will be detected and completely realized by the wind conversion system during on and off peak hours of the wind power plant operation); the requirement of utilization is about 30% of electrical energy, 30% of heat energy and 30% of production hydrogen; the requirement of keeping intermittency to about 20% of the market penetration successfully manageable (utilization the variable electrical power by local usages permanently is equal to increase intermittency up to about 60% of market penetration); the requirement of cost reduction of the wind conversion system by utilizing one or two blade wind turbines; the requirement of cost reduction of the wind conversion system by integration its system into already built the current electrical grid.

The features and preferences of the present method and system based thereon is illustrated by the following figures by way of example which are not necessarily drawn to scale and not limiting in the figures of the accompanying drawings and the following detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a fluctuated wind speed and kinetic wind energy;

FIG. 2 illustrates a basic of current and present methods of extraction mechanical power from the wind;

FIG. 3 illustrates a basic of a current method of utilizing a six-pulls diode rectifier.

FIG. 4 illustrates a basic of a present method of utilizing a six-pulls diode rectifier.

FIG. 5 illustrates a basic of a present method of utilizing the always fluctuating wind.

FIG. 6 is a kinematic view of a one blade wind turbine system.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides the method of direct conversion the always fluctuating wind energy into variable electrical power, consuming its variable electrical power with accordance of the equation (1) and wind conversion system based thereon method.

FIG. 1 illustrates a fluctuated wind speed and kinetic wind energy. In the present drawing graph 1 represents fluctuated wind speed and graph 3 represents fluctuated wind kinetic energy. Wherein, graph 1 above and below line 2 represents dynamic and static part of wind speeds; graph 3 above and below line 4 represents dynamic and static part of wind kinetic energies; curve (A-B) represents positive slope (increasing wind speed); curve (B-C) represents negative slope (decreasing wind speed).

FIG. 2 illustrates a basic of current and present methods of extraction mechanical power from the wind. The current method of extraction mechanical power from the wind is the indirect conversion wind kinetic energy into the average mechanical power M presented on the shaft. The steps of the conversion the wind kinetic energy into the average mechanical power M presented on the turbine shaft comprises: partially converting the wind kinetic energy into the average mechanical power M during rotation the blade above the hub; partially converting the wind kinetic energy into mechanical kinetic energy of the rotated wind turbine above the hub; converting the wind kinetic energy into the mechanical power M2 below the hub; converting the produced and stored kinetic mechanical energy on the wind turbine above the hub into the mechanical power M3+M4 during rotation blade below the hub; and forming the average mechanical power M on the shaft as M=M2+M3+M4. Wherein, the mechanical powers M3 and M4 compensate losses dependable on the wind shear and blade pass the tower. The average mechanical power M rotate the wind turbine with constant speed above and below the hub see FIG. 2, line 2. Then it's produced average mechanical power M converts into electricity by the electrical generator. The current method of indirect conversion wind kinetic energy into the average mechanical power on the shaft makes the wind conversion system e.g. three blade wind turbine system unstable. More than it is impossible to keep stability of the wind conversion system without exploit of the rotor masses as a fly-wheel. Typically the fly-wheel masses proportional to the length of blades, number of blades, material needed to build blades, hub, gearbox and generator masses, torque, airfoil, and design tip speed. The choice of the blade length is a trade-off between sites that have a low, medium, or high annual average wind speed. Masses of three blades wind turbine makes wind conversion system more inertial. This fact contradicts to capture maximum power from the always fluctuating wind. Also for large wind turbine increases cyclic loads due to vertical wind shear, unpredictable wind gust, gravity and yaw/tilt. The influence of cyclic loads to the wind conversion system e.g. gearbox and generator explains below.

Assume the wind speed increases and decreases above and below the shaft and represented on FIG. 1 as positive (A-B) and negative (B-C) slopes of wind speed during one rotation of the wind turbine. Extra wind kinetic energy produces above the hub converts into kinetic mechanical energy in the form of speed up the wind turbine rotation. During the wind turbine rotation below the hub the average mechanical power includes the extra mechanical power converted from stored mechanical kinetic energy on rotated wind turbine and mechanical power produced by wind kinetic energy (negative (B-C) slope) is not sufficient for keeping the average mechanical power on the shaft and keeping a wind turbine rotation as constant parameter. Result of imbalances produced mechanical power above and below the hub that is speed up and slow down the wind turbine rotation (cycling) and makes vibration in the wind conversion system e.g. rotor, drive train, gearbox, generator and influences to the electrical grid stability.

The current method of conversion the variable kinetic wind energy into the average electrical power is based on the following equation P−Pc−Pv=0. Wherein: functions P and Pc are mutually dependable functions; electrical power P is an outcome of the wind kinetic energy; constant electrical power Pc feeds the electrical grid; variable electrical power Pv=0 and P−Pc=0. And mutually dependable functions P and Pc means any changes in the unpredictable part of wind influences to the voltage and frequency of electrical generator connected to the electrical grid. For maintaining the voltage and frequency of electrical grid in the strictly limited ranges needed to install costly equipment, such as a doubly-fed induction generator and/or full AC-DC-AC power convertor. The current method of maintaining the voltage and frequency of electrical grid in the strictly limited ranges never allows the wind conversion system to operate with maximum efficiency. Because keeping the constant electrical power connected to the grid contradicts to the instantly conversion of the always fluctuated wind kinetic energy into the variable (cyclic) electrical power during each rotation of the wind turbine and more than to the requirement of successfully manageable an intermittency is about 20% of market penetration.

The present method of direct conversion of wind kinetic energy into variable mechanical power includes: eliminating step of exploit the wind turbine as a fly-wheel masses; instantaneously converting of all predictable static (constant) and unpredictable dynamic (variable) parts of naturally blowing the always fluctuated wind into the variable mechanical power; speed up and slow down of the wind turbine rotation following to the cycling mechanical power above and below the hub see FIG. 2, curb 1.

The present method of extraction of the variable electrical power from the variable mechanical power is also based on the following equation P−Pc−Pv=0; wherein P, Pc are mutually independent functions, P and Pv are variable functions, Pc is a constant function and represents predictable static part of the wind, and Pv as a variable function represents unpredictable dynamic part of the wind.

The features of the current method of utilizing the variable electrical power are illustrated in FIG. 3.

FIG. 3 illustrates a basic of a current method of utilizing a six-pulls diode rectifier. In this embodiment the six-pulls diode rectifier converts 3-phase AC voltages into unfiltered six-pulse DC voltage Vu through a six diode bridge rectifier and feed the load through the smoothened capacitor Vc. In the FIG. 3 drawn process of charging capacitor Vc through an input phases A-B and A-C. Wherein, at the time when the input voltages A-B and A-C are higher than the capacitor voltage Vc, the AC current IA=Ic+Ir drawn from its phases charges the capacitor (Ic) and feeds the load (Ir) simultaneously. The charging zones a-b and c-d is lasting 30 degrees for each double peak AC current 1 A and third phases C (curve f-g) and B (curve n-o) inside the charging zones a-b and c-d are not involved in the process of charging capacitor.

When the capacitor voltage Vc is higher than the input voltages A-B and A-C the capacitor alone feeds the DC-AC power inverter Ic=Ir, see AC zero current zones b-c and d-e. The discharging process is lasting 30 degrees for each zero current zone wherein, voltages as curves g-h, m-n, r-s, o-p, t-q and k-l are not involved in the process of feeding the load. These unusable voltages presented in the zero and peak current zones counts is about 50% of power loses during 2π period (360 degree) and, more than, its power makes inconvenience for utilization and transmission the electrical power. For utilization and transmission its inconvenience of electrical power necessary to build special schemes, involve expensive passive and active filters, reactive components, electronic devices, doubly-fed induction generator and special transformers, such as transformer with isolated delta and Y configuration is needed for building a 12 pulls rectified DC voltages wherein, disadvantage of building the 12 pulls rectified DC voltages that are increased unusable phases from 1 to 4 because in the rectification process instantly involved only two phases.

Typically, the cheapest way of utilization its inconvenience of electrical power that is to the smoothened capacitor adds an inductor at the input AC or DC output of the six-pulls diode rectifier. Its technique permits to charge the capacitor over a longer period of time, by means to reduce the AC currents zero zones and harmonics due to distortion of a sine wave by nonlinear peak currents. “The add inductor can reduce typical distortion levels from more than 80% to less than 20% THD” [17]. But the “voltage of a third phase” is never involved in the process of charging capacitor and also inconvenience for transmitting. Wherein, “the voltage of a third phase” is a combined voltage inside any of two other phases that is involved in the process of charging the capacitor. Furthermore, the produced harmonics due to distortion of a sine wave is a source of heating the generator and transmission lines. Furthermore, for maintaining the double AC peak currents needed for charging the capacitor and feeding the DC-AC power inverter simultaneously it is necessary at least doubling torques drawn from the wind turbine and generator. Furthermore, increasing the generator torque T=kΦI means the increasing iron and copper masses wherein, T-torque; k-constant; Φ-magnetic flux; I-current. Furthermore, increasing torque produced by the wind turbine means the increasing masses of blades, hub, drive train, and tower.

The present method permits to resolve some disadvantages belong to the current power conversion system comprising: eliminating peak currents drawn (torque) from the electrical generator; reducing iron and copper masses; reducing a value of the DC power capacitors in the AC-DC-AC power converters; increasing power coefficient; reducing complexity, weight and cost of the wind turbine.

FIG. 4 illustrates a basic of a present method of utilizing variable electrical power. The present method of production and consuming the variable electrical power with accordance of the equation (1) satisfy: the requirement of completely consuming the mechanical power produced by the wind turbine; utilization 30% of electrical energy, 30% of heat energy and 30% of production hydrogen; strictly is limitation to the voltage and frequency of produced electricity connected to the grid; desirable limitation to the voltage and frequency of produced electricity connected to the local usages e.g. production of heat, hydrogen and compressed air. The present method of production and consuming the variable electrical power with accordance of the equation (1) is based on: keeping the voltage at the capacitor Vc below the rectified unfiltered six pulls voltage Vu; keeping the voltage at the capacitor Vc as constant parameter; drawing AC current from three phases of the electrical generator simultaneously e.g. drawing electrical power from the third phase. The above features will be explained in detail below.

FIG. 5 illustrates a basic of a present method of utilizing the always fluctuated wind. Referring to FIG. 5, the wind turbine system includes: wind turbines 1, 21; three phases generators 2, 22; six-pulse diode rectifier 7, 13, 23; six-pulse transistor rectifier 4; switches 12, 24; variable voltage heat energy exchangers 3, 8-11, 25; DC-AC inverter 14; capacitors 5, 16; DC local consumers 17; AC local consumers 18; transformer 15. The heat energy exchangers may include resistor or set of resistors and switches. The electronic switches, such as Insulated Gate Bipolar transistor (IGBT) or thyristors and mechanical switches connected in parallel to transistors (not shown). The mechanical switches turn on during emergency stopping of the wind turbine e.g. broken DC-AC power inverter, Grid, or even one or two phases of generator. The local usages of DC electricity produce heat, hydrogen and compressed air. The local usages of AC electricity means TV, computers, lights, conditioner and appliances e.g. electrical stove. The two of the one blade wind turbines is chosen as example of possibility to extraction of a worseness cycling mechanical power from the wind, converting its worseness cycling mechanical power into variable electrical power and fully utilizing its variable electrical power with good performance and lowest cost of wind turbines. The operation and features of two of the one blade wind turbines will be explained later.

The basic of the present method of utilization an always fluctuating wind comprises: converting the fluctuated wind into variable mechanical power through the wind turbines 1 and 21; converting the mechanical power into the variable voltage and frequency alternate current (AC) power P through generators 2 and 22; converting its variable voltage and frequency AC power P into the unfiltered DC variable six-pulse voltage powers Pv through the six-pulse diode rectifiers 4, 13 and 23; converting the unfiltered DC variable six-pulse voltage Vu into the constant voltage Vc at the capacitor 16 through the heat energy exchangers 8-10, Vu=Vr+Vc wherein, Vr-variable voltage drops around the heat energy exchanger; inverting through the DC-AC power inverter 14 the constant voltage power at the capacitor U16 into a stable voltage and frequency AC power with accordance to the voltage and frequency parameters requested by the electrical grid codes; feeding the AC local usages 18 with a stable voltage and frequency AC power; transmitting the stable voltage and frequency AC power through the transformer 15 into the grid; converting the variable voltage and frequency AC powers Pv into the heat in the resistors 3, 11 and 25. Wherein, the heat energy exchangers 8-10 consume variable part Vr of the variable six-pulse voltage Vu. Its consuming variable part of the voltage Vu permit to keep the constant voltage on the capacitor 16 and DC-AC power inverter 14, keep the variable six-pulse voltage Vu is higher than the DC voltage at the capacitor 16 and reducing harmonics in the AC and DC lines. The value of the resistors are chosen permits to: limit current drawn from the generator at the time of starting to charge the capacitor from zero to nominal voltage; feeding the DC-AC power inverter at maximum allowable cycling rotational speed of the wind turbine; varying wind turbine rotational speed, for example, between +/−15% of the rated wind turbine speed. The six-pulls diode rectifier 13 operates at the time of starting wind turbines 1 and 22 and feeding the local usages of DC electricity at low or absent wind.

The inconvenience of the AC electrical power drawn from third phase of the electrical generator V1 converts into heat through the three switches 24 and three resistors 25 is connected to the neutral line (heat energy exchanger 11 and switches set 12 has a similar design). In other embodiments the inconvenience electrical power drawn from third phase V1 converts into DC constant voltage Vc at the capacitor 5 through the six-pulls transistor rectifier 4 and heat energy exchanger 3. The constant DC power feeds the local usages 6. In sill other embodiments the inconvenience electrical power drawn from third phase V1 of the generator at first converts through step up transformer (not shown) into the variable AC voltage V1 equal to the variable AC voltages produced by the generator, then its variable AC voltage V1 converts into the constant DC voltage at the capacitor through the six-pulls transistor rectifier 4 and heat energy exchanger 3 and feeds local usages or the DC-AC inverter (not shown).

The extra electrical power produced by the wind turbine with accordance of the equation [1] should be consume by the constant voltage DC and AC local usages 6, 17, 18, Grid and heat energy exchangers 3, 8, 9, 25. Wherein, it will be P=P6+P17+P18+Pgrid+P3+P8+P25.

During low wind blow the electrical power produced by the wind turbines combines with electrical power transmitted from the Grid and consumes by the constant voltage DC and AC loads 6, 17, 18 and heat energy exchangers 3, 8-11, 25. Wherein, it will be P+Pgrid=P6+P17+P18+P3+P8+P9+P10+P11+P25. Utilization of the heat energy exchanger 11 helps to keep in the grid the power coefficient more efficient.

The control system regulates the extra electrical power consuming by the grid by increasing or decreasing the constant DC voltage Vc at the capacitor 16 by balancing at the DC local usages 17 and heat energy exchangers 8-10 of consumption of the electrical power.

The proposed scheme permits to realize the present method of instant extraction of the variable electrical power from the fluctuated wind and based on: sensing any kinetic wind energy changes; instant extraction and fully converting its kinetic wind energy into variable electrical power; utilizing all produced electrical power during on/off peak hours; utilizing all produced electrical power with accordance of the equation (1); utilizing by local usages of AC electricity with accordance of the electrical grid codes; utilizing by local usages of DC electricity with accordance of the desirable limitation to the voltage for production of the heat, hydrogen, compressed air and warm water. Wherein, production of the heat and warm water or hydrogen or compressed air dependent on seasons and installation wind turbine at the north or south of the countries.

The exemplary of consuming the variable electrical power with accordance of the equation (1) described herein, shown in the FIG. 5 represents only preferred embodiment of the invention. Indeed, various modifications and additions may be implemented and adapted the present invention for production of the variable AC power by park of one blade wind turbines, utilization DC transmission cables as capacitor, installing the heat energy exchangers on the wind turbine or customer's sides, in variety of cost reduction different applications e.g. based on co-generation and integration technologies. Wherein, co-generation technology means production of both electricity and heat energy simultaneously and integration technology means production of electricity by the wind turbine-generator and gas-turbine generator simultaneously. In the integration process involves the inconvenience variable electrical power in the form of heat produced by the wind turbine and compressed air produced by the tide, and/or wave, and/or river kinetic energies compressors. The product of integration process such as the hot compressed air converts into electricity through the gas-turbine generator and combines with the electrical power produced by the wind turbine and feeds the grid or at the time of low wind and wave kinetic energies are present the all variable electrical power produced by the wind turbine converts into heat, combines with compressed air produced by tide, and/or wave, and/or river compressors and through the gas-turbine generator converts into electricity and feeds the electrical grid alone.

A non-transitory computer readable media storing a program, wherein the program instructs a processor to perform a method for operating wind turbine system comprising: conversion of the always fluctuating wind into variable electrical power, consuming its variable electrical power with accordance of the equation P−Pc−Pv=0; utilizing three phases of an electrical generator simultaneously; keeping the unfiltered voltage on rectifiers is higher than the DC constant voltage at the capacitor; keeping the DC voltage at the DC capacitor as a constant parameter. Wherein, in the P, Pc, and Pv powers the aerodynamic end, profile and whirlpool loses; blade numbers, mechanical and heat loses, such as loses in the gearbox, electrical generator, converter, inverter and battery, transformer, heat energy exchangers; air and hydrogen compressors and air, hydrogen and electrical transmission lines is not analyzed and considered in the present invention.

FIG. 6 is a kinematic view of the one blade wind turbine system. Referring to FIG. 6 the one blade wind turbine system includes: swept blade tip 1; blade base 2; pitch mechanisms 3; wind turbine carousel 4; flat circle road 5; main frame 6; counterweight 8; bears 7 and 9; bolts 10; tower 12. The counterweight 8: statically balances the masses of swept blade 1, base blade 2 and pitch mechanisms 3; absorbs a high level of vibration. Wind turbine masses e.g. counterweight masses keep on the main frame 6. The collected on the carousel 4 mechanical powers (torque) spins the flat road 5 through the counterweight 8. Wherein, flat circle road 5 means a DDPM generator rotor or one stage planetary gears box.

In the present embodiment the wind turbine converts fluctuated wind kinetic energy into variable mechanical power (torque) on the carousel 4. Its collected mechanical power at the carousel through the counterweight 8 rotates the DDPM generator. The steps of minimizing cost of the present wind turbine system comprising: downwind mode of operation; eliminating peak current drawn from the generators; driving more mechanical power from rotational speed than torque with accordance of equation P=M*V, P-mechanical power, M-torque, V=ω*R-DDPM generator rotor speed, ω-angular velocity, R-radius. The method of eliminating peak currents drawn from the generators permits to lowering active length of generators, air gap of the generators, masses of the wind turbine and DDPM generator, structure materials needed to build the carousel and tower, gearbox, hydraulic system and supporting bears. The speed of the DDPM generator rotors dependant on rotational speed (rpm) of the one blade wind turbine, radius of the carousel 4, flat circle road 5 or one stage planetary gears ratio and multiple generator rotor radiuses (not shown). The present one blade wind turbine design comprises: only on limitation to the carousel radius, length of the blade hord line, tip speed, weights of the blade, root base e.g. pitch mechanism and counterweight; eliminating a blade root section e.g. blade-root joint section and hub; utilization two supporting bears 7 and 9; utilization of the non-twisted blades; building wind turbine system in the form of module; utilization the swept blade tips 1 up to permissible tip speed for low noise environment e.g. night time and for large rotor diameter manufactories utilize tip speed is about (80-100) m/s in the high noise environment. According to the utilization of the swept blade tips 1 rotation at the low or high noise environment the pitch mechanism to control: rotational speed and power of the wind turbine; angle of attack of the entire blade into or out of the wind; air loads such as flapwise, edgewise and torsion on base of the blade and tower; bubals noise presented on trailing edge of the swept blade tip; disabling the swept blade tip after the nominal turbine speed, rated power and maximum permissible tip speed are reached by means to separate the blade tip from the base blade and turning angle of attack of the entire swept blade tip 1 into position where lift coefficient is zero or during emergency e.g. high wind speed, the swept blade tip 1 is acting as brake tip. The chosen base blade length is about 25 m permits: assembling and maintaining wind turbine systems on the land; installation wind turbines on the tower without cranes; and using regular trucks for transportation wind turbines to the wind power plant. The tower height is about 130 m is chosen: for the low wind sites; by analyzing a triton data such as average wind shear and percentage of wind speed within range versa to height, probability density within range versa to wind speed; by balance material costs of the tower against expensive permanent magnet and cupper materials needed to build DDPM generators. Wherein: swept area covers by the two of the one blade wind turbines is about 6770=(3846−461)*2 sq. meters see FIG. 5 and takes into account blade base length 25 m, swept blade tip length 6 m, carousel radius 4 m and losses is about 6% e.g. blades pass the tower and front of carousel's area; rated wind turbine power dependent on permissible tip speed; rated mechanical power on the low wind shaft P=0.5*ρ*Cp*(πr²)*V³, Cp—power conversion coefficient of the rotor; (πr²)—swept area by the rotor (m²); V—wind speed (m/s); ρ—air density (kg/m³). The chosen tip speed ratio is about λ=9.4 satisfies to maximum Cp power coefficient versa of equation of the tip speed ratio λ=4 π/n, where n—number of blades and for n=1, λ=12.56 and n=3, λ=4.19. According to “Parametric study for large wind turbine blades” [1] the “thicker” and “thickest” distributions utilize airfoils that have significantly increased thickness to improve structural performance, reduce weight and cost because it's cheaper to increase solidity for the one blade wind turbine by means of reducing the tip speed ratio from λ=12.56 to λ=9.4 than to reduce solidity for three blade wind turbine by means increasing the tip speed ratio from λ=4.19 to typical λ=6-8. More than, the three blade wind turbine after the rated power are reached begin to operate with power coefficient Cp in average is about 0.25 and for typical power capacity wind cites is about 35% its means that the wind turbine system e.g. gearbox, electrical generator, tower and transmission lines is overweighed. 

What is claimed is:
 1. A variable speed wind turbine comprising: an electrical generator coupled to at least an one blade wind turbine; a six-pulls diode rectifier coupled to the electrical generator; a variable heat energy exchanger coupled to the output of the six-pulls diode rectifier and another side of the variable heat energy exchanger coupled to a DC capacitor, DC-AC inverter and DC constant voltage local usages; output of the DC-AC inverter coupled to the AC local usages of electricity and electrical grid; a six-pulls transistor rectifier coupled to the electrical generator; a second variable heat energy exchanger coupled to an output of a six-pulls transistor rectifier and another side of the second variable heat energy exchanger coupled to a second DC capacitor and second constant voltage local usages; a second variable heat energy exchanger coupled to a neutral line through switches.
 2. The variable speed wind turbine of claim 1, wherein one blade wind turbine comprises blade, carousel, counterweight and two supporting bears.
 3. The variable speed wind turbine of claim 2, wherein stored at the carousel mechanical power produced by the one blade wind turbine provides a variable mechanical power to an electrical generator through a counterweight.
 4. The variable speed wind turbine of claim 1, wherein an electrical generator provides electrical power for a DC and AC local usages and grid simultaneously.
 5. The variable speed wind turbine of claim 4, wherein a generator provides electrical power for a DC and AC local usages and grid by drawing power from two phases of a generator.
 6. The variable speed wind turbine of claim 4, wherein a generator provides electrical power for a DC local usages by drawing power from third phases of a three AC phases of a generator.
 7. The variable speed wind turbine of claim 1, wherein a generator provides electrical power for a DC and AC local usages and power grid through a variable heat energy exchangers.
 8. The variable speed wind turbine of claim 7, wherein the variable heat energy exchangers provide conversion of the variable electrical power into heat.
 9. The variable speed wind turbine of claim 4, wherein local usages comprises production of heat, hydrogen and compressed air.
 10. The variable speed wind turbine of claim 1, wherein the variable heat energy exchanger comprises at least one resistor and switch.
 11. A method for operating a variable speed wind turbine comprising steps of: converting a fluctuating wind into a variable mechanical power by at least one blade wind turbine, wherein the mechanical power is collected on the carousel and transmitted from the carousel to an electrical generator through the counterweight; converting the variable mechanical power into a variable voltage and frequency AC power by an electrical generator; converting the variable voltage and frequency AC power into a variable six pulls DC power through a six-pulls diode rectifier; converting the variable voltage and frequency AC power into a variable six pulls DC power through a six-pulls transistor rectifier, converting a variable six pulls DC power into constant voltage DC power through a variable heat energy exchanger and DC capacitor; converting the constant voltage DC power into an AC power through a DC-AC power inverter connected in parallel to the DC capacitor; drawing AC currents from three AC phases of a generator simultaneously for feeding local usages and grid; permanently keeping the rectified unfiltered variable DC voltage is higher than a DC constant voltage at the capacitor.
 12. A non-transitory computer readable media storing a program, wherein the program instructs a processor to perform a method for operating wind turbine system comprising: conversion of the always fluctuating wind into variable electrical power, consuming its variable electrical power with accordance of the equation P−Pc−Pv=0; drawing AC currents from three phases of a generator simultaneously for feeding local usages and grid; permanently keeping the rectified unfiltered variable voltage is higher than a DC constant voltage at the capacitor. 